Presentation is loading. Please wait.

Presentation is loading. Please wait.

Agenda Monday –Diffraction – Problems –How small? –How many? Tuesday –Diffraction – Laboratory, Quiz on Interference Wed –Review Fri –Bonus Quiz.

Published byJorge Rosborough Modified over 10 years ago

Similar presentations

Presentation on theme: "Agenda Monday –Diffraction – Problems –How small? –How many? Tuesday –Diffraction – Laboratory, Quiz on Interference Wed –Review Fri –Bonus Quiz."— Presentation transcript:

1 Agenda Monday –Diffraction – Problems –How small? –How many? Tuesday –Diffraction – Laboratory, Quiz on Interference Wed –Review Fri –Bonus Quiz

2 Basic Diffraction Formula  x = m (constructive)  x = (m+1/2) (constructive) –m integer Open question –What is  x?

3 Multiple Slits  x = m (constructive)  x = (m+1/2) (constructive) –m integer Open question –  x = dsin 

4 Equation vs. Experiment Coherent, monochromatic Light wavelength Slits (Turned perp.) Rectangular Screen m 3 2 1 0 -2 -3  dsin(  ) = m d

5 Examine Situation for Given Laser Means: fixed Coherent, monochromatic Light wavelength Slits (Turned perp.) Screen m 3 2 1 0 -2 -3  dsin(  ) = m d

6 Range of possible d values? Given: fixed Coherent, monochromatic Light wavelength Slits (Turned perp.) Screen m 3 2 1 0 -2 -3  dsin(  ) = m d

7 Range of possible d values? Given: fixed dsin(  ) = m d = m / sin(  ) Anything related to range of d? Try big & small….

8 Range of possible d values? Given: fixed dsin(  ) = m d = m / sin(  ) How big can d be? Pretty big, m can range to infinity…. If d is big, what happens to angle? sin(  ) = m /d…. Large slit spacing, all diffraction squeezed together Interference exists – just all overlaps – beam behavior

9 Large Distance (Assume large width…) Coherent, monochromatic Light wavelength Slits (Turned perp.) Screen d dsin(  ) = m Slit one Slit Two

10 Range of possible d values? Given: fixed dsin(  ) = m d = m / sin(  ) How small can d be? Pretty small, m can be zero How about for anything but m = 0 Smallest  m =1 d = /sin(  ) d small when sin(  ) big, sin(  ) <= 1 smallest d for m=1 diffraction: d = Replace: sin(  )=m sin(  ) = m implies if d =, three diffraction spots if d <, no diffraction (m=0?)

11 Range of possible d values? Given: fixed Coherent, monochromatic Light wavelength Slits (Turned perp.) Screen m 1 0 dsin(  ) = m d ~

12 What Happens? Diffraction from spacing & width –Overlaying patterns, superposition 3 slits, all same spacing –Very similar to two slits Tons of slits, all same spacing –Refined interference. Focused maxima Move screen farther away from slits –Bigger angle/distance on screen Move light source, leave rest same –Nothing

13 Resolution When can you identify 2 objects? Coherent, monochromatic Light wavelength Slits (Turned perp.) Screen m 1 0 dsin(  ) = m d ~ w ~ Not Here…

14 Resolution When can you identify 2 objects? Begin with diffraction Diffraction of light through a circular aperture 1 st ring (spot)  sin(  ) = 1.22 /D Same setup idea as before

15 Resolution When can you identify 2 objects? Begin with diffraction Diffraction of light around a circular block 1 st ring (spot)  sin(  ) = 1.22 /D Same setup idea as before Things that might cause diffraction rings… Pits/dust on glasses Iris of your eye Telescope Lens Raindrops

16 Pretty Picture Moon Raindrop What you see

17 Headlights Resolved (barely) Unresolved

18 Issue How close must a car be before you can tell it is NOT a motorcycle. (assume both headlights work) sin(  ) = 1.22 /D 1.5 m  Small Angle sin(  ) ~ tan(  ) ~  [radians]

19 Issue How close must a car be before you can tell it is NOT a motorcycle. (assume both headlights work)  = 1.22 /D  = y/L What is D? 1.5 m = y  Small Angle sin(  ) ~ tan(  ) ~  [radians] L

20 Issue How close must a car be before you can tell it is NOT a motorcycle. (assume both headlights work)  = 1.22 /D  = y/L pupil: D ~ 5 mm What is ? 1.5 m = y  Small Angle sin(  ) ~ tan(  ) ~  [radians] L

21 Issue How close must a car be before you can tell it is NOT a motorcycle. (assume both headlights work)  = 1.22 /D  = y/L pupil: D ~ 5 mm GREEN ~ 500 nm Calculation Time 1.5 m = y  Small Angle sin(  ) ~ tan(  ) ~  [radians] L

22 Issue How close must a car be before you can tell it is NOT a motorcycle. (assume both headlights work)  = 1.22 /D  = y/L y/L = 1.22 /D L/y = D/(1.22 ) 1.5 m = y  Small Angle sin(  ) ~ tan(  ) ~  [radians] L = 500 nm D = 5 mm

23 Issue How close must a car be before you can tell it is NOT a motorcycle. (assume both headlights work)  = 1.22 /D L/y = D/(1.22 ) L = Dy/(1.22 ) = 12km ~ 7 miles Little far, but not crazy far aberrations blur image more here 1.5 m = y  Small Angle sin(  ) ~ tan(  ) ~  [radians] L = 500 nm D = 5 mm

24 Agenda Monday –Diffraction – Problems Tuesday –Diffraction – Laboratory, Quiz on Interference Wed –Review Fri –Bonus Quiz

Download ppt "Agenda Monday –Diffraction – Problems –How small? –How many? Tuesday –Diffraction – Laboratory, Quiz on Interference Wed –Review Fri –Bonus Quiz."

Similar presentations

1308 E&M Diffraction – light as a wave Examples of wave diffraction: Water waves diffract through a small opening in the dam. Sound waves diffract through.

1308 E&M Diffraction – light as a wave Examples of wave diffraction: Water waves diffract through a small opening in the dam. Sound waves diffract through.
AP Physics Mr. Jean March 22th, 2012. The plan: –Wave interference –Double Slit patterns –Check out chapter #24 Giancoli.

AP Physics Mr. Jean March 22th, The plan: –Wave interference –Double Slit patterns –Check out chapter #24 Giancoli.
Diffraction The bending/spreading of waves as they go through gaps or around edges The effect is greatest when gap width is equal to or smaller than the.

Diffraction The bending/spreading of waves as they go through gaps or around edges The effect is greatest when gap width is equal to or smaller than the.
last dance Chapter 26 – diffraction – part ii

last dance Chapter 26 – diffraction – part ii
AP Physics Mr. Jean March 30 th, 2012. The plan: Review of slit patterns & interference of light particles. Quest Assignment #2 Polarizer More interference.

AP Physics Mr. Jean March 30 th, The plan: Review of slit patterns & interference of light particles. Quest Assignment #2 Polarizer More interference.
WAVE INTERFERENCE.....

WAVE INTERFERENCE.....
Chapter 24 Wave Optics.

Chapter 24 Wave Optics.
UNIT 8 Light and Optics 1. Wednesday February 29 th 2 Light and Optics.

UNIT 8 Light and Optics 1. Wednesday February 29 th 2 Light and Optics.
What’s so Special about a Laser?

What’s so Special about a Laser?
Lecture 33 Review for Exam 4 Interference, Diffraction Reflection, Refraction.

Lecture 33 Review for Exam 4 Interference, Diffraction Reflection, Refraction.
Announcements 11/19/10 Prayer TA won’t have office hours on Tuesday next week (even though Tuesday = Friday classes). Neither will I. (HW 36 = only 2 problems.)

Announcements 11/19/10 Prayer TA won’t have office hours on Tuesday next week (even though Tuesday = Friday classes). Neither will I. (HW 36 = only 2 problems.)
PHY 1371Dr. Jie Zou1 Chapter 37 Interference of Light Waves.

PHY 1371Dr. Jie Zou1 Chapter 37 Interference of Light Waves.
Announcements 11/18/11 Prayer Labs 8, 9 due tomorrow Lab 10 due Tuesday Exam 3 review session: Mon 5-6 pm, room ??? (I’ll tell you on Monday) Exam 3 starts.

Announcements 11/18/11 Prayer Labs 8, 9 due tomorrow Lab 10 due Tuesday Exam 3 review session: Mon 5-6 pm, room ??? (I’ll tell you on Monday) Exam 3 starts.
Interference and Diffraction

Interference and Diffraction
PHY 1371Dr. Jie Zou1 Chapter 38 Diffraction and Polarization (Cont.)

PHY 1371Dr. Jie Zou1 Chapter 38 Diffraction and Polarization (Cont.)
Chapter 25: Interference and Diffraction

Chapter 25: Interference and Diffraction
Chapter 16 Interference and Diffraction. 16.1 - Interference Objectives: Describe how light waves interfere with each other to produce bright and dark.

Chapter 16 Interference and Diffraction Interference Objectives: Describe how light waves interfere with each other to produce bright and dark.
I NTERFERENCE AND D IFFRACTION Chapter 15 Holt. Section 1 Interference: Combining Light Waves I nterference takes place only between waves with the same.

I NTERFERENCE AND D IFFRACTION Chapter 15 Holt. Section 1 Interference: Combining Light Waves I nterference takes place only between waves with the same.
Topic 9.2 is an extension of Topic 4.4. Both single and the double-slit diffraction were considered in 4.4. Essential idea: Single-slit diffraction occurs.

Topic 9.2 is an extension of Topic 4.4. Both single and the double-slit diffraction were considered in 4.4. Essential idea: Single-slit diffraction occurs.
Goal: To understand diffraction Objectives: 1)To learn about the results of Young’s Double Slit Experiment 2)To understand when you get maxima and minima.

Goal: To understand diffraction Objectives: 1)To learn about the results of Young’s Double Slit Experiment 2)To understand when you get maxima and minima.

Similar presentations

Ads by Google